Abstract
Theory and empirical data showed that two processes can boost selection against deleterious mutations, thus facilitating the purging of the mutation load: inbreeding, by exposing recessive deleterious alleles to selection in homozygous form, and sexual selection, by enhancing the relative reproductive success of males with small mutation loads. These processes tend to be mutually exclusive because sexual selection is reduced under mating systems that promote inbreeding, such as self‐fertilization in hermaphrodites. We estimated the relative efficiency of inbreeding and sexual selection at purging the genetic load, using 50 generations of experimental evolution, in a hermaphroditic snail (Physa acuta). To this end, we generated lines that were exposed to various intensities of inbreeding, sexual selection (on the male function), and nonsexual selection (on the female function). We measured how these regimes affected the mutation load, quantified through the survival of outcrossed and selfed juveniles. We found that juvenile survival strongly decreased in outbred lines with reduced male selection, but not when female selection was relaxed, showing that male‐specific sexual selection does purge deleterious mutations. However, in lines exposed to inbreeding, where sexual selection was also relaxed, survival did not decrease, and even increased for self‐fertilized juveniles, showing that purging through inbreeding can compensate for the absence of sexual selection. Our results point to the further question of whether a mixed strategy combining the advantages of both mechanisms of genetic purging could be evolutionary stable.
Highlights
Natural selection is often considered as an improvement process, progressively increasing the adaptation of organisms to their environment
Our study provides strong support to the theory of genetic purging by sexual selection
We tested this theory for the first time in hermaphrodites and confirmed that suppressing selection on the female function did not compromise genetic purging as much as suppressing sexual selection on the male function
Summary
Natural selection is often considered as an improvement process, progressively increasing the adaptation of organisms to their environment. Lumley et al (2015) recently showed that the suppression of sexual selection for many generations through imposed monogamy or highly female-biased sex-ratios resulted in elevated genetic loads in flour beetles This type of studies yielded overall inconsistent results (Whitlock and Agrawal 2009). Other studies tracked the fate of a limited number of purely deleterious mutations introduced, induced or accumulated de novo in populations (Radwan 2004; Hollis et al 2009; McGuigan et al 2011; Arbuthnott and Rundle 2012; Almbro and Simmons 2014; Grieshop et al 2016; Singh et al 2017) instead of the standing load. These mutations, represent a small fraction of the genome (and a small expected cumulative effect) compared to the typical standing mutation load of natural populations
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